International Journal of Environmental & Agriculture Research (IJOEAR)
ISSN:[2454-1850]
[Vol-7, Issue-2, February- 2021]
Effect of Tillage Practices on Selected Soil Properties in Sudan Savanna Agro-Ecology of Nigeria Usman, M.1*, Ali, A.2, Agber, P.I.3 *1
Department of Agricultural Science Education, Federal College of Education (Technical), Potiskum-Nigeria 2,3 Department of Soil Science, Federal University of Agriculture, Makurdi-Nigeria *Corresponding Author’s Received: 27 January 2021/ Revised: 8 February 2021/ Accepted: 14 February 2021/ Published: 28-02-2021 Copyright @ 2021 International Journal of Environmental and Agriculture Research This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (https://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted Non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
Abstract— Field experiments were carried out in 2018 and 2019 cropping seasons to evaluate the effect of tillage practices on selected soil properties in Sudan Savanna Agro-ecology of Nigeria. Treatments consisted of zero tillage, flat beds and ridges, and were laid out in a randomized complete block design (RCBD) and replicated three times. Prior to experiment, surface (0-15 cm) soil samples were collected from eight points and bulked; post-harvest composite soil samples were also collected on the basis of treatments and were analyzed using standard analytical procedures. NCRIBEN-01M variety of sesame was used as the test crop for both cropping seasons. The data generated from the study were subjected to Analysis of Variance (ANOVA) using Genstat Release 10.3 DE after which significant means were separated using Least Significant Difference (LSD) at 5 % level of probability. Based on the findings of this study, there were significant effects of tillage practices with respect to most soil parameters studied in 2018 and 2019 cropping seasons. The effects of tillage practices on soil nutrients indicated that the zero tilled plots had higher nutrients and organic matter, followed by the flat beds while the ridged plots gave lower values for essential nutrients and organic matter in both cropping seasons. For conservation or retention of essential nutrients as well as organic matter in soil, zero tillage is recommended for the study area. Keywords— Soil properties, Sudan Savanna, Tillage Practices, Nigeria.
I.
INTRODUCTION
Tillage is performed to loosen the soil and produce a good tilth. Tillage requirement of a crop is site, environment and soil type specific (Ojeniyi and Agboola, 1995). Tillage contributes up to 20 % amongst crop production factors (Adekiya and Ojeniyi, 2011). Tillage operations in various forms have been practiced from the very inception of growing crop plants (Sharma and Behera, 2008). To prepare a virgin or fallow land and use it for growing crops, tillage in any form is an indispensable practice even today. Tillage is one of the forms of management practices of soil, water, nutrient, crop and pests. Tillage helps to replace natural vegetation with useful crops and is necessary to provide a favourable edaphic environment for the establishment, growth and yield of crop plants (Sharma et al., 2002). After harvest of the crop, soil becomes hard and compact. Beating action of rain drops, irrigation and subsequent drying, movement of inter-cultivation implements and labour cause soil compaction. Seeds need loose, friable soil with sufficient air and water for good germination. The field should be free from weeds to avoid competition with the crop. It should also be free from stubbles to facilitate easy and smooth movement of sowing implements. There have been conflicting reports on the influence of tillage on soil chemical properties; likewise contradictory reports as to the superiority of crops on tilled plots to those of no-till plots have been documented (Adekiya and Ojeniyi, 2011). Ridge tillage was found to increase growth of okra on ultisol of central Southwest, Nigeria relative to no-tillage (Ojeniyi and Adekayode, 1999). However, manual tillage systems including ridges, heaps and flat beds have been reported to degrade soil quality and reduce chemical and biological qualities especially on alfisols in the rainforest areas of Southwest, Nigeria (Busari and Salako, 2013). The study of relative effect of ridging and no-tillage on soil properties and yield of sweet potato in guinea savanna zone (middle belt) of Nigeria showed that no-till gave higher tuber yield of sweet potato compared to ridging, which was adduced to have higher moisture content, N, P, K, Ca and Mg status (Ojeniyi, 1993). In Nigeria, farmers commonly till the soil to improve its physical, chemical, and biological characteristics that alter plant growth and yield (Agber et al., 2017). Crops grown without tillage are stunted and show symptoms of water and nutrient deficiencies because of high surface bulk Page | 9
International Journal of Environmental & Agriculture Research (IJOEAR)
ISSN:[2454-1850]
[Vol-7, Issue-2, February- 2021]
density, low porosity, retarded infiltration, and low water holding capacity of the soil (Ali et al., 2015). However, the conventional and traditional tillage methods have negative effects on soil life and increase mineralization of organic matter. A zero tillage system, on the other hand, is a conservation method that involves the use of crop residues that aid water infiltration, prevent erosion, and increase organic matter content and agricultural productivity (Ali et al., 2015). Soil properties describe the physical and chemical characteristic behaviour of soils including the nutrient status (Usman, 2017). The need for basic knowledge and assessment of changes in soil properties and their fertility status with time to evaluate the impact of various tillage practices has become necessary for sustainable agriculture in Nigerian savanna zones. Similarly, for sustainable soil nutrient management in these zones, there is also need for an understanding of how soil responds to tillage practices over time (Oyedele et al., 2014). One of the major important components of agricultural management and sustainability as well, a goal of most farmers in the tropics is the maintenance of soil nutrients and qualities. This according to Mallo (2010) provides avenue for measuring levels of crop productivity. Soil properties reveal soil quality which measures the levels of soil fertility. This means that assessing soil quality also involves measuring and evaluating soil properties for optimum crop yield. Soil properties may have influence on various processes that are suitable for agricultural practices, though the dynamic soil nature describes the condition of a specific soil due to management practices. However, for sustainable crop production, there is need for adoption of improved tillage practices and proper soil management that would ensure optimum crop yield. The knowledge of tillage and soil properties in Nigerian savanna is necessary in addressing the problem of low crop productivity and to ensure optimum food production. Thus, the objective of this study was to provide documented information on the effect of tillage practices on post harvest soil properties of sesame fields in the study area.
II. 2.1
MATERIALS AND METHODS
Experimental Site
Field experiments were carried out in 2018 and 2019 cropping seasons to evaluate the effect of tillage practices on post harvest selected soil properties of sesame fields at the Research Farm of the Federal College of Education (Technical), Potiskum, Yobe State-Nigeria. NCRIBEN-01M variety of sesame was used as the test crop for both cropping seasons. Treatments consisted of zero tillage, flat beds and ridges, and were laid out in a RCBD and replicated three times. The study location falls within the Sudan Savanna Agro-ecology of Nigeria with mean rainfall of about 800 mm per annum and temperature of 39 – 42 0C. It is located between latitude 11042ꞌ N to 11043ꞌ N and longitude 11004ꞌ E to 11006ꞌ E (YSGN, 2008). 2.2
Soil Data Collection and Analysis
Prior to experiment, surface (0-15 cm) soil samples were collected from eight points and bulked; post-harvest composite soil samples were also collected on the basis of treatments. The soil samples taken from each plot according to treatment were air dried; crushed and sieved using 2 mm sieve and analyzed using standard soil analytical procedures at the Department of Soil Science, University of Maiduguri, Nigeria. Particle size distribution was determined by the Hydrometer method (Bouyocous, 1951). Soil pH was measured with the glass electrode pH meter in soil solution ratio 1: 2 in 0.01 M CaCl 2. Soil organic carbon (OC) was determined by the Walkey and Black method. Total N by the macro-Kjeldahl digestion method (Bremner and Mulraney, 1982), Available P was determined by Bray and Kurtz (1945) extraction method. Exchangeable cations were extracted using NH4OAC solution, K and Na were read using flame photometer, while Ca and Mg was determined using the Atomic Absorption Spectrophotometer (AAS). Effective cation exchange capacity (ECEC) was established as the summation of the exchangeable cations (K, Na, Ca, Mg) and exchange acidity. The data generated from the study were subjected to Analysis of Variance (ANOVA) using Genstat Release 10.3 DE after which significant means were separated using Least Significant Difference (LSD) at 5 % level of probability.
III. 3.1
RESULTS AND DISCUSSION
Selected Soil Properties of the Experimental Site before Planting
The results of analysis of selected soil properties of the experimental site before planting are presented on Table 1. The results indicated that soils for both cropping seasons were sandy clay loam in texture. This texture is ideal for crop production as crops require soils that are well drained for optimum growth and yield. The high sand content of the soils in 2018 and 2019 respectively (67.10 – 65.00 %) was indicative of the low clay content (21.20 – 20.90 %) for both years which could be attributed to the soil separates sorting activities by organisms, clay eluviation, surface soil erosion, parent material Page | 10
International Journal of Environmental & Agriculture Research (IJOEAR)
ISSN:[2454-1850]
[Vol-7, Issue-2, February- 2021]
or a combination of these factors (Malgwi et al., 2008). The slightly acidic pH of the soils (6.96 – 6.70) also indicate that the soils are suitable for crop production as this pH range is the optimum pH for most crops and microbial activities in soil. The results of physical and chemical properties of the experimental site before planting (Table 1) indicates a poor soil fertility status that requires fertilizer application to replenish nutrients taken out from the soil through crop harvest and to supplement nutrients to boost yields (Olatunji and Ayuba, 2012). The values of SOM (1.95 and 0.98 %) for the two cropping seasons were below the average range of 2.5- 2.6 % considered for good crop growth (Aduayi et al., 2002) in the study area. The results of the soil analysis thus indicated that soil amendment was required in line with earlier observation by Agboola (1975) who reported that farmers in Africa requires adequate soil amendment for good crop production as a result of low inherent soil fertility. In addition, the poor nutrient status of this soil is characteristic of many tropical soils where the slash and burn practice coupled with high insolation and rainfall prevents the build-up of organic matter which is the store house of most nutrients (Aduayi et al. (2002; Anjembe, 2004; Senjobi et al. (2013).
TABLE 1 SELECTED SOIL PROPERTIES OF THE EXPERIMENTAL SITE BEFORE PLANTING IN POTISKUM Property
2018
2019
pH
6.96
6.70
Organic Carbon (%)
0.55
0.57
Organic Matter (%)
1.95
0.98
Total Nitrogen (%)
0.17
0.19
3.15
3.30
Ca
3.10
2.83
Mg
2.80
2.60
K
0.24
0.22
Na
0.03
0.02
EB
6.17
5.67
EA
0.20
0.18
CEC
6.37
5.85
Base Saturation (%)
96.86
96.92
Sand (%)
67.10
65.00
Silt (%)
11.70
14.10
Clay (%)
21.20
20.90
Textural Class
Sandy clay loam
Sandy clay loam
Chemical Property
-1
Available P (mgkg ) -1
Exchangeable Cation (Cmol kg )
Particle Size Distribution
3.2
Main Effect of Tillage Practices on Selected Soil Properties
The main effects of tillage practices on selected soil properties are presented on Table 2a-c. The effect of tillage practices on soil properties also show significant difference in most of the soil parameters studied in 2018 and 2019 cropping seasons. Tillage operations are known to influence both the release and conservation of soil nutrients. The effects of tillage practices on nutrients indicated that the zero tilled plots had higher nutrients followed by the flat beds while the ridged plots had the least available in both years. The higher nutrient status of zero tillage can be attributed to the presence of mulch on the surface due to decomposed plant residues, which led to enhanced soil organic matter status and associated availability of nutrients (Agbede, 2008). Tillage systems that reduce soil disturbance and residue incorporation have generally been observed to increase soil organic matter content (Mrabet et al., 2001). Ismail et al. (1994) concluded that conservation tillage systems results in significant and positive effects on several chemical soil properties. Soil organic matter largely contributes to nutrient cycling and thus supplies of N, S and other elements as well (Saleque et al., 2009). Page | 11
International Journal of Environmental & Agriculture Research (IJOEAR)
ISSN:[2454-1850]
[Vol-7, Issue-2, February- 2021]
TABLE 2 a MAIN EFFECT OF TILLAGE PRACTICES ON SELECTED SOIL PROPERTIES IN POTISKUM BS (%)
Tillage Practices Flat Ridged Zero LSD (P≤0.05)
2018 88.17 89.22 88.42 0.14
CEC Ca (cmol kg-1) (cmol kg-1) 2018 2019 2018 2019 6.40 6.48 3.54 3.57 6.16 6.22 3.29 3.32 6.47 6.57 3.62 3.65 NS 0.19 0.22 0.16 NS= Not Significant
2019 91.76 89.61 92.84 1.35
EA (cmol kg-1) 2018 2019 0.47 0.52 0.57 0.64 0.37 0.42 0.08 0.05
EB (cmol kg-1) 2018 2019 5.93 5.96 5.56 5.58 6.10 6.06 0.39 0.32
K (cmol kg-1) 2018 2019 0.27 0.34 0.25 0.25 0.28 0.28 NS 0.15
TABLE 2 b MAIN EFFECT OF TILLAGE PRACTICES ON SELECTED SOIL PROPERTIES IN POTISKUM Tillage Practices Flat Ridged Zero LSD (P≤0.05)
Mg (cmol kg-1) 2018 2019 1.50 1.51 1.45 1.45 1.83 1.56 0.22 NS
N (%) 2018 0.083 0.079 0.083 0.002
Na (cmol kg-1) 2019 2018 2019 0.083 0.62 0.62 0.085 0.57 0.57 0.079 0.64 0.64 0.004 0.04 0.05 NS= Not Significant
OC (%) 2018 0.88 0.86 0.89 NS
OM (%) 2019 0.88 0.86 0.89 0.12
2018 1.52 1.49 1.54 NS
2019 1.51 1.48 1.54 0.10
P (mg kg-1) 2018 2019 3.29 3.30 3.91 3.92 3.30 3.32 0.312 0.25
TABLE 2 c MAIN EFFECT OF TILLAGE PRACTICES ON SELECTED SOIL PROPERTIES IN POTISKUM
Flat Ridged Zero LSD (P≤0.05)
Sand (%)
pH
Tillage Practices 2018 6.57 6.56 6.61 NS
2019 6.62 6.57 6.56 NS
2018 2019 71.78 71.73 72.60 72.35 70.43 70.36 1.49 1.34 NS= Not Significant
Clay (%) 2018 15.07 14.54 16.13 0.72
Silt (%) 2019 15.07 14.54 16.22 0.65
2018 13.15 12.86 13.43 0.34
2019 13.20 13.11 13.43 NS
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International Journal of Environmental & Agriculture Research (IJOEAR)
ISSN:[2454-1850]
[Vol-7, Issue-2, February- 2021]
Several researchers observed an increase of soil organic matter and carbon with conservation tillage practices in the top soil layer (Bronick and Lal, 2005; Vogeler et al., 2009; Powlson et al., 2012; Schjonning and Tomsen, 2013). In general, tillage improves the decomposition of crop residues by facilitating contact between plant tissue and soil aggregate surfaces, the primary biome of soil microorganisms (Bronick and Lal, 2005). In addition, tillage and organic matter in the soil and improves the availability of nutrients for plant growth through the formation of clay humus complexes and the increase of charged surfaces for nutrient binding. Accumulation of considerable amounts of total nitrogen, phosphorus (P), and potassium with conservation tillage was observed (Calegari et al., 2013; Spiegel et al., 2007). This may be due to the fact that the land was not disturbed which increased the buildup of soil organic matter, resulting in high organic carbon which reflects a reduced rate of leaching in the soil profile in the soil studied. Tillage systems (zero tillage) that reduce soil disturbance and residue incorporation have generally been observed to increase organic C. Zero tillage has been reported to have resulted in increased in organic C content which in turn enhances soil quality and resilience (Abid and Lal, 2008). Differences in available N among tillage systems observed in the current study are in agreement with those of other studies (Martin-Rueda et al., 2007). Available N was significantly higher in zero tillage treatment than in the other tillage systems. Similarly, a study on Mollisols in Nebraska, available N was significantly greater under zero tillage than conventional tillage (Martin-Rueda et al., 2007). In another study, soil available N content was also significantly increased under zero or minimum tillage (Martin-Rueda et al., 2007). Higher Nitrogen in the zero tilled soils may be attributed to less loss through immobilization, volatilization, denitrification, and leaching (Malhi et al., 2001). Available P and K as well as other essential nutrient elements were higher under zero treatment probably due to higher soil organic C level. Zibilske et al. (2002) reported that improvement of soil available P was due to redistribution or mining of P at lower soil depths. Also, work done by Redel et al. (2007) showed a high amount of P under zero tillage treatment compared to the conventional tillage and have attributed this to an increase in contact time between P and soil particles. Cultivation also stimulates soil carbon losses due to accelerated oxidation of soil carbon by microbial action. Hence when organic matter is lost the associated nutrients are also lost. Yin and Vyn (2002) also observed more soil nutrients in case of no-tillage as compared to deep tillage. The least values of essential nutrients recorded by the ridged plots compared with the zero tilled plots could be due to inversion of top soil during soil preparation, which brought less fertile subsoil to the surface in addition to possible leaching (Ali et al., 2006) as well as rapid mineralization and uptake of nutrients by the crops (Adekiya et al., 2009). Similarly, Alam et al., (2014) reported that tillage practices showed positive effect on soil properties and crop yields, Bulk and particles densities were decreased due to tillage practices having the highest reduction of these properties and the highest increase of porosity and field capacity in zero tillage. The highest total N, P, K and S in their available forms was recorded in zero tillage. Therefore, zero tillage was found to be suitable for soil health and achieving optimum crop yields.
IV.
CONCLUSION AND RECOMMENDATIONS
Based on the findings in this study, there were significant effects of tillage practices with respect to most parameters studied in 2018 and 2019 cropping seasons. The effects of tillage practices on nutrients indicated that the zero tilled plots had higher nutrients and organic matter, followed by the flat beds while the ridged plots gave lower values for essential nutrients and organic matter in both cropping seasons. For conservation or retention of essential nutrients as well as organic matter in soil, zero tillage is recommended in the study area.
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